4 Advice to Choose a Graphite Block for Mold

4 steps to select the correct graphite product

If you want to learn more, please visit our website Graphite Block for Mold.

Graphite is an ideal EDM material. The right graphite opens the door to another EDM world. However, only if it has been selected carefully for your application.. And that is easy to do with our help. Just follow the steps below.

Step 1: Determine the required surface finishing
Step 2: Choose the graphite grade
Step 3: Check the available block sizes
Step 4: Order or request the graphite product

Step 1: Determine the required surface finishing

 The surface finishing that needs to be realized depends on the application of the electrode. 

           

Performance surface finishing

This category of graphite is typically used for:

• large surface areas
• (rough) machining of plastic mold & die-casting tools
   

 

 

Fine 

surface finishing

This category of graphite is typically used for:
 

• detailed electrodes
• plastic injection molds
• small hole drilling

   

Medium 

surface finishing

This category of graphite is typically used for:
 

• roughing or finishing electrodes
• large electrodes
• applications that require low wear

 

Extra fine 

surface finishing

This category of graphite is typically used for:
 

• fine detailed electrodes
• delicate electrodes
• threading electrodes

           

The required surface finishing is also available as a product filter in the webshop.

 

Step 2: Choose the graphite grade

 Once the required finishing grade is determined, the graphite grade can be selected.

Finishing grade Grade  Av. part. size Grade Av. part. size Performance           Technograph-8 13 Technograph-10  11 Technograph-15 11 Medium EDM-200 10 Technograph-20 7 EDM-C200  10  Technograph-25 7 Technograph-30 7 Fine   EDM-1 <5 Technograph-35   4 EDM-3 <5 EDM-C3  <5 Extra fine  EDM-4 <4 Technograph-40 2 EDM-AF5  <1 Technograph-45 3

 An overview of typical applications per graphite grade is available as well. 

Specifications per graphite grade

 

Performance surface finishing grades

  Average particle
size (µm)

Specific gravity (gr/cm³) 

Flexural strength (kg/cm

³)

Hardness (Shore) Electrical resistivity (µ 

Ω cm)

Technograph-8 13 1.8 400 56 1200 Technograph-10 11 1.85 510 58 1100 Technograph-15 11 1.85 510 58 1100

 

Medium surface finishing grades

 

Average particle
size

(µm)

Compressive Strength (kg/cm

³)

Flexural Strength (kg/cm

³)

Hardness (shore) Electrical Resistivity 

 (µ 

Ω cm)

EDM-200 10 1075 635 68 1475 EDM-C200 10 1631 851 62 290

 

  Average particle
size (µm)

Specific gravity (gr/cm³) 

Flexural strength (kg/cm

³)

Hardness (shore) Electrical resistivity
(µ 

Ω cm)

Technograph-20 7 1.83 550 62 1250 Technograph-25 7 1.82 650 64 1350 Technograph-30 7 1.82 650 64 1350

 

 

 Fine surface finishing grades

  Average particle size 

(µm)

Compressive Strength (kg/cm

³)

Flexural strength (kg/cm

³)

Hardness (shore) Electrical resistivity 

(µ 

Ω cm)

EDM-1 <5 998 682 69 1930 EDM-3 <5 1273 935 73 1560 EDM-C3 <5 1993 1427 66 325

  

  Average particle size (µm)

Specific gravity (gr/cm³) 

Flexural strength (kg/cm

³)

Hardness (shore) Electrical resistivity
(µ 

Ω cm)

Technograph-35 4 1.82 670 72 1650

 

 

 Extra fine surface finishing grades

 

Average particle
size 

(µm)

Compressive Strength (kg/cm

³)

Flexural strength (kg/cm

³)

Hardness (shore) Electrical resistivity 

(µ 

Ω cm)

EDM-4 <4 1511 1230 76 1270 EDM-AF5 <1 1554 1019 83 2160

  

  Average particle
size (µm)

Specific gravity (gr/cm³) 

Flexural strength (kg/cm

³)

 Hardness (shore) Electrical resistivity
(µ 

Ω cm)

Technograph-40 2 1.84 900 78  1550 Technograph-45 3 1.84 900 78  1550

  

 Step 3: Check the available block sizes for the selected graphite grade

 

 

Graphite

 

Available sizes                             

Novotec part
complete block

Technograph 8

325 x 660 x 1350 mm

02.08.001

 

Technograph 10
 

325 x 660 x 1350 mm

02.10.005

 

Technograph 15 

325 x 660 x 1350 mm

02.15.001 

Technograph 20

 

245 x 480 x 1280 mm
320 x 635 x 1300 mm

02.20.001
02.20.005 

Technograph 25

 

245 x 480 x 1250 mm
315 x 635 x 1280 mm

02.25.001
02.25.007

 

Technograph 30

 

315 x 635 x 635 mm

02.30.004

 

Technograph 35 

 

245 x 480 x 1250 mm
315 x 635 x 1280 mm

02.35.002
02.35.006

Technograph 40
 

120 x 320 x 930 mm

02.40.002

 

Technograph 45
 

120 x 320 x 465 mm

02.45.001

 

EDM-180
 

165 x 625 x1530 mm

02.65.001

Contact us to discuss your requirements of high-purity graphite block. Our experienced sales team can help you identify the options that best suit your needs.

Related links:
Ultimate Guide to 2mm Graphite Block Mould

 

EDM-200
 

165 x 625 x1530 mm

02.68.020

 

EDM-1
 

115 x 310 x 1020 mm

02.70.101

 

EDM-3
 

115 x 310 x 1020 mm

02.80.101

EDM- 4 

115 x 310 x 1020 mm

02.91.002

 

EDM-AF5

55 x 210 x 310 mm
55 x 155 x 310 mm

02.85.001
02.85.035
 

EDM-C200
 

110 x 210 x 310 mm

02.69.001

 

EDM-C3

55 x 155 x 310 mm
55 x 210 x 310 mm
110 x 130 x 210 mm
40 x 105 x 460 mm

02.95.001
02.95.002
02.95.003
02.95.060

 

 

Step 4: Order or request the graphite product

Complete graphite blocks can be ordered directly in the Novotec webshop.

For pieces "made to order" a quotation can be requested online. 

Tips & tricks for pieces/ blocks made to order

Please not that besides size and finishing  other parameters also influence the price of your graphite order.  When requesting a custom size sawed/ machined graphite piece, it is good to take into account:

• The available block sizes in the required grade
• The size of the individual workpieces
• The order quantity in relation to the work piece size (especially if the same size is ordered on a regular basis).

Please feel free to contact Novotec for a calculation of your ideal order quantity . Especially if size and quantity are a bit flexible, in many cases price advantages can be realized. 

Examples

Requesting the individual sizes that are required may result in less residue material, then ordering it in one piece.

 If smaller pieces are ordered on a regular basis, determining the optimal order quantity is recommendable.

Novotec experts are available to give specialized advice by phone, email or on location. Contact Novotec for more information. 

Sinker EDM burning into H13 tool steel with a graphite electrode. Images courtesy of Toyo Tanso Ltd.

Diagram of the graphite manufacturing process. Diagram courtesy of Toyo Tanso Ltd.

Lloyd Booth from Aimmco in Woodland, WA measuring a fine rib of graphite.

High-speed milling centers feeding an EDM cell at M&M Mold.

Ken at M&M Mold putting a rib into a connector mold with an electrode on an EDM machine.

Moldmaking in the present day has seen many technological advances throughout the realm of EDM. We have seen significant upgrades in sinker machines that compensate for potential deficiencies in running conditions. The implementation of automation is commonplace to combat rising labor costs. Quick change tooling aids in rapid turn-around. One thing operators rarely consider as an area of technological significance is the graphite consumables they use.

 

Graphite Manufacture

Graphite takes roughly six months to manufacture from beginning to end. During this process a meticulous observation of quality needs to take place throughout every step of production. This begins in the selection of raw materials. Different sources for coal tar pitch and coke materials result in different final properties for the graphite that is produced.

These raw materials are crushed and sieved numerous times to ensure the con-sistency of the resultant particles. The mix-ing then occurs to ensure the particle distribution is correct. This mixture is placed in rubber sleeves and put into an isostatic press. Isostatic means constant pressure. This piece of equipment is crucial to ensure the properties in the block are isotropic. Iso-tropic generally means that the graphite will have homogeneous or similar properties throughout the block and consistent quality.

After the blocks are removed from the press they are still in the green stage—meaning they need to be transformed through heat treatment from carbon to graphite. Each graphite grade has a particular heat treat recipe that aids in the final formulation and will help determine the properties it will possess.

Graphite is baked at a very slow rate to ensure the gases within the blocks are not released too rapidly. That would cause an increased rate of cracked blocks. Some grades can be re-impregnated with pitch at pressure to ensure higher densities and baked a second time. The last step is a high temperature graphitization process that will complete the transformation from carbon to graphite by adjusting the crystalline structure of the material.

It is imperative that during every step along the manufacturing process quality checks are performed to ensure the graphite blocks meet quality standards. It also is important that the graphite manufacturer works to improve the performance of the graphite it makes. Employing a large staff of engineers who constantly develop grades for the ever-changing EDM marketplace is essential.

 

Choosing the Correct Grade

Now that we know generally how graphite is made, how do we choose the correct grade? In order to maintain cost effectiveness, an EDM shop needs to choose EDM graphite that provides dependable quality at a good price. The incorrect selection of consumables can cause the operation to take longer than planned or cost more than what was budgeted. If an improper grade was chosen, the customer may experience undesired results or pay too much for a grade that they did not require.

When looking at roughing grades they generally have a particle size around 10 to 8 microns. They are used for applications that require no detail and no sharp edges or corners. Because of the molecular and bonding structure in this grade class, you will experience high removal rates at the expense of high electrode wear. Although this grade class machines somewhat easily—due to its structure—there is an issue with it chipping and breaking with small electrodes.

Once you enter the finishing/detail aspect of the grade selection process, you will find that the grades generally have particle sizes from 8 to 5 microns. The most common application for this grade class is forging dies and die cast molding dies. They also can be used in less complex powdered and sintered metal applications, and for larger plastic injection parts. The downfall to these grades is that they are limited on strength and you cannot produce thin fragile electrodes, or superior surface finishes either.

If the workpiece requires smaller and more intricate features, sharper corners, thin ribs or fine detailed smaller electrodes, another grade class usually is required. The fine/detail category will provide the necessary results. These grades usually have a particle size from 3 to 5 microns.

When the application calls for wire cutting, aerospace applications, blow molding, plastic injection, threading electrodes or medical applications, the fine/detail category will meet all of your needs. These applications require that the graphite provides sharp corners, superior surface finishes, and exhibits high strength for small and thin electrode applications.

There are applications that require ultra fine surface finishes, extremely small parts, intricate details on the electrode, best wear conditions, precision or thin wire cutting and superior electrode wear. If this is the prerequisite then the precision class will work best for them. The particle size for this grade class ranges from 3 to 1 micron. It works exceptionally when applied to exotic aerospace type metals (high nickel and copper alloys) and carbide applications.

Finally, there also are copper-impregnated grades that provide an advantage over non-impregnated grades. Typically companies impregnate two classes of graphites: (1) the finishing/detail grades and (2) the fine detail grades.

When graphite is impregnated with copper, micron size particles of copper fill in the holes (otherwise known as porosity) of the graphite structure. By impregnating the graphite with copper it increases the graphite’s electrical resistivity and strength.

Now the electrode manufacturer has the ability to make extremely thin and fragile electrodes, such as a very thin deep rib electrode. Copper-impregnated graphites also are the preferred grades for aerospace applications because the added copper helps to stabilize machining of exotic, copper and nickel alloys.

If you require the finest finish available, impregnated graphites provide the absolute finest finish. Copper-impregnated grades also allow for stable machining when nonfavorable conditions exist—such as poor flushing or when the operator is not very experienced with the application.

 

Summary

With all of the different grades of graphite available, if an incorrect decision is made, and the wrong grade is used in an application, the result could be costly in both profitability and delivery. However, if educated on what to expect from each grade class and manufacturer, the venture should prove to be a profitable and timely success.

Are you interested in learning more about graphite crucibles in different sizes? Contact us today to secure an expert consultation!